A method and apparatus is provided for controlling the optical output power from an optical amplifier arrangement. The arrangement includes a rare-earth doped fiber for imparting gain to an optical input signal propagating therethrough, a pump source for supplying pump power to the rare-earth doped fiber, and a tap for receiving a portion of the output power generated by the rare-earth doped fiber and converting it to a control signal. A controller is also provided for receiving the control signal and generating a bias current in response thereto for driving the pump source. The method begins by receiving an optical input signal that is being amplitude modulated at a prescribed frequency. The slew rate of the controller is adjusted so that the bias current drives the pump source to generate pump power that cannot vary at a rate greater than a slew-rate limit established by the controller. In this way resonance between the input signal and the frequency of the feedback control loop can be avoided.
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17. An optical amplifier arrangement comprising:
a rare-earth doped fiber for imparting gain to an optical input signal propagating therethrough; a pump source for supplying pump power to the rare-earth doped fiber; a tap for receiving a portion of the output power generated by the rare-earth doped fiber and converting said portion of the output power to a control signal; and a controller receiving the control signal and generating a bias current in response thereto for driving the pump source, said controller including a user-adjustable slew rate limiter for selectively adjusting the slew rate of the controller.
9. A method for controlling the optical output power from an optical amplifier arrangement that includes a rare-earth doped fiber for imparting gain to an optical input signal propagating therethrough, a pump source for supplying pump power to the rare-earth doped fiber, a tap for receiving a portion of the output power generated by the rare-earth doped fiber and converting said portion of the output power to a control signal, and a controller receiving the control signal and generating a bias current in response thereto for driving the pump source, said method comprising the steps of:
receiving an optical input signal being amplitude modulated at a prescribed frequency; and adjusting the slew rate of the controller so that a control loop resonant frequency is offset from the prescribed frequency at which the optical input signal is being modulated.
1. A method for controlling the optical output power from an optical amplifier arrangement that includes a rare-earth doped fiber for imparting gain to an optical input signal propagating therethrough, a pump source for supplying pump power to the rare-earth doped fiber, a tap for receiving a portion of the output power generated by the rare-earth doped fiber and converting said portion of the output power to a control signal, and a controller receiving the control signal and generating a bias current in response thereto for driving the pump source, said method comprising the steps of:
receiving an optical input signal being amplitude modulated at a prescribed frequency; and adjusting the slew rate of the controller so that the bias current drives the pump source to generate pump power that cannot vary at a rate greater than a slew-rate limit established by the controller.
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The present invention relates generally to optical amplifiers, and more particularly to an optical amplifier arrangement having a controller with a user-adjustable slew-rate limiter.
Currently, transmission systems employed in the cable television industry provide two-way transmission of information (e.g., video, multimedia and/or data) between the headend and a plurality of subscribers. Typically, the headend transmits the information destined for individual subscribers in an optical format, via one or more fiber optic links to one or more optical nodes. Each node converts the optically formatted downstream information into electrical signals for distribution, typically via a cable plant having a hybrid fiber/coax (HFC) architecture, to individual subscribers. In addition to receiving the downstream information, each individual subscriber may generate information in the form of voice, data, or a combination thereof, destined for the headend. En route to other subscribers or service providers, the subscriber-generated information is segmented by the coaxial cable plant and passes it to the node for conversion into an optical format for transmission to the headend.
Such transmission systems typically employ optical amplifiers along the fiber optic links to amplify the optical signals being transmitted. One example of a conventional optical amplifier is a rare-earth doped optical amplifier, which uses rare-earth ions as the active element. The ions are doped in the fiber core and pumped optically to provide gain. The silica fiber core serves as the host medium for the ions. While many different rare-earth ions such as neodymium, praseodymium, ytterbium etc. can be used to provide gain in different portions of the spectrum, erbium-doped fiber amplifiers (EDFAs) have proven to be particularly attractive because they are operable in the spectral region where optical loss in the fiber is minimal. Also, the erbium-doped fiber amplifier is particularly useful because of its ability to amplify multiple wavelength channels without crosstalk penalty, even when operating deep in gain compression. EDFAs are also attractive because they are fiber devices and thus can be easily connected to other fiber links with low loss.
Optical amplifiers often employ electronic feedback arrangements to control the output power from the amplifier. For example, the feedback arrangement may be used to provide a constant gain or a constant output power. One limitation of conventional optical amplifiers that employ a feedback arrangement to control the output power is that they typically offer a fixed frequency response. This presents a problem if the modulation frequency of the input signal is in resonance with the frequency of the feedback control loop. In this case the output power from the amplifier may undergo an additional amplification on the output that is undesirable. To avoid this problem, manufacturers typically set the frequency response to a fixed value that is low enough so that most frequencies at which the input signal is likely to undergo modulation will not create a resonance condition. While this is often a satisfactory approach, it hampers the response time of the optical amplifier.
Accordingly, there is need for a more flexible optical amplifier arrangement whose frequency response can be controlled to offer a fast response time and the ability to properly handle low frequency modulated input signals under appropriate circumstances.
In accordance with the present invention, a method and apparatus is provided for controlling the optical output power from an optical amplifier arrangement. The arrangement includes a rare-earth doped fiber for imparting gain to an optical input signal propagating therethrough, a pump source for supplying pump power to the rare-earth doped fiber, and a tap for receiving a portion of the output power generated by the rare-earth doped fiber and converting it to a control signal. A controller is also provided for receiving the control signal and generating a bias current in response thereto for driving the pump source. The method begins by receiving an optical input signal that is being amplitude modulated at a prescribed frequency. The slew rate of the controller is adjusted so that the bias current drives the pump source to generate pump power that cannot vary at a rate greater than a slew-rate limit established by the controller. In this way resonance between the input signal and the frequency of the feedback control loop can be avoided.
In accordance with one aspect of the invention, the optical output power from the optical amplifier is monitored and the slew rate is automatically adjusted in accordance therewith.
In accordance with another aspect of the invention, the power of the optical input signal is monitored and the slew rate is automatically adjusted in accordance therewith. In some cases the slew rate is automatically lowered when the power of the input signal fluctuates at a rate greater than a prescribed value. Moreover, the slew rate may be automatically increased to its previous value when the power of the input signal no longer fluctuates at a rate greater than the prescribed value.
In accordance with another aspect of the invention, an optical amplifier arrangement is provided which includes a rare-earth doped fiber for imparting gain to an optical input signal propagating therethrough. A pump source supplies pump power to the rare-earth doped fiber. The arrangement also includes a tap for receiving a portion of the output power generated by the rare-earth doped fiber and converting it to a control signal. A controller receives the control signal and generating a bias current in response thereto for driving the pump source. The controller includes a user-adjustable slew rate limiter for selectively adjusting the slew rate of the controller.
In accordance with yet another aspect of the invention, the user-adjustable slew rate limiter is hardware-controllable. Alternatively, the user-adjustable slew rate limiter may be software-controllable.
In operation, the optical signal to be amplified is input via port 4 and combined with the optical pump signal output from laser 2 so that the signal is amplified in the erbium doped fiber 1 in a conventional manner. Tap 12, which may be a fused fiber coupler, for example, splits off a small proportion of the signal input to the fiber 1. This small part of the input signal, which is optionally employed as an input control signal, is detected by detector 14, amplified by electronic amplifier 16 and applied to the controller 10. Likewise, tap 5, which may also be a fused fiber coupler, for example, splits off a small proportion of the amplified signal output from fiber 1. This small part of the amplified signal, which serves as an output control signal, is detected by detector 8, amplified by amplifier 9 and applied to the feedback circuit 10. Controller 10 determines the amplifier gain based on the output control signal and possibly on the input control signal as well. The output from the feedback circuit 10 is applied to the pump laser 2 and serves to vary the pump laser 2 output power to maintain, for example, constant gain or constant output power.
Controller 10 may use a variety of different approaches to determine the bias current applied to the pump laser 2. For example, controller 10 may be proportional, proportional-integral, or proportional-integral-differential in nature. If controller 10 is a proportional-integral-differential (PID) controller, for instance, the bias current will be the sum of the proportional, integral and differential control terms. The controller 10 may be configured in any manner known to those of ordinary skill in the art. For example, it may be implemented with either digital or analog electronics and in hardware or a combination of hardware and software.
A problem may arise in the EDFA arrangement depicted in
The present inventors have recognized that the undesirable output power fluctuations that arise at or near the resonant frequency of the control loop can be removed by the addition of slew-rate limiting to the control signal of the controller. Slew-rate limiting of the control signal prevents the control signal from changing more rapidly than the slew-rate limit. Removal of the resonant condition in the controller by addition of a control signal slew-rate limit greatly enhances the ability of the optical amplifier to control differing input signals.
Referring again to
By allowing the user to adjust the slew-rate of the optical amplifier arrangement the user can tailor its modulation frequency response to their application-dependent needs. That is, instead of being limited to an optical amplifier with a fixed frequency response the user now has an optical amplifier with an adjustable modulation frequency response.
A user-adjustable slew-rate limiter in accordance with the present invention can be implemented in a number of different ways that are known to those of ordinary skill in the art. Different implementations may be chosen in part on the amplifier frequency response that is desired. For example, a hardware controlled slew-rate limiter would allow an output response that could be adjusted over a very wide range of modulation frequencies, but which would be incapable of handling low frequency modulations. This is a fundamental limitation because the size of the integrating capacitors (and their associated leakage current) that are needed at such frequencies creates a lower bound for lower frequency responses that approach 1 Hz. On the other hand, a software-controlled slew-rate limiter allows the frequency response to go to much lower frequencies than if it were implemented in hardware. Alternatively, if the adjustable slew-rate limiter were implemented in a digital signal processor (DSP), the frequency response could achieve a compromise between the hardware and software implementations. That is, a DSP would allow the controller's frequency response to encompass a wide range while still being usable at extremely low frequencies.
In one embodiment of the invention the adjustable slew-rate limiter may be under the active control of software. In this way the slew-rate limit could be adjusted in real-time by the software to provide an optimal response for any given application. The active control may be performed by monitoring the variations in the output power and increasing the slew-rate limit until the output power returns to a substantially constant value. Alternatively (or in addition), active control may be performed by monitoring the optical input signal and when the input signal fluctuates at a rate greater than some predefined value the slew-rate limit could be lowered for the duration of the time that the input signal is fluctuating above this value. When the input signal is no longer fluctuating so rapidly, the slew-rate limit could be returned to its previous setting.
In a preferred embodiment of the invention, if the input signal is being monitored in the aforementioned manner it may also be advantageous to calculate its Fast-Fourier-Transform (FFT) so that the slew-rate limit could be set to the precise value that gives the best overall response, but which is still lower than the resonant frequency of the control loop. The FFT could be performed, for example, in a DSP. Because most applications will not likely need the optical amplifier to provide an immediate change in its response, the FFT could be processed over a substantially longer time period than the response time of the control loop. One particular advantage of this approach is that there is no need to change the controller constants, making the overall frequency control significantly easier to implement once the desired frequency response is known.
Converse, Eric James, Ciaffa, David, Donaldson, Charles John
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